US2225335A - Current converting contactor mechanism - Google Patents

Current converting contactor mechanism Download PDF

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US2225335A
US2225335A US25523939A US2225335A US 2225335 A US2225335 A US 2225335A US 25523939 A US25523939 A US 25523939A US 2225335 A US2225335 A US 2225335A
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contactor
source
input leads
current converting
current
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Frank X Dostal
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TRANSFORMER CORP
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TRANSFORMER CORP
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    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02MAPPARATUS FOR CONVERSION BETWEEN AC AND AC, BETWEEN AC AND DC, OR BETWEEN DC AND DC, AND FOR USE WITH MAINS OR SIMILAR POWER SUPPLY SYSTEMS; CONVERSION OF DC OR AC INPUT POWER INTO SURGE OUTPUT POWER; CONTROL OR REGULATION THEREOF
    • H02M1/00Details of apparatus for conversion
    • H02M1/20Contact mechanisms of dynamic converters
    • H02M1/28Contact mechanisms of dynamic converters incorporating electromagnetically-operated vibrating contacts
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02MAPPARATUS FOR CONVERSION BETWEEN AC AND AC, BETWEEN AC AND DC, OR BETWEEN DC AND DC, AND FOR USE WITH MAINS OR SIMILAR POWER SUPPLY SYSTEMS; CONVERSION OF DC OR AC INPUT POWER INTO SURGE OUTPUT POWER; CONTROL OR REGULATION THEREOF
    • H02M7/00Conversion of ac power input into dc power output; Conversion of dc power input into ac power output
    • H02M7/42Conversion of dc power input into ac power output without possibility of reversal
    • H02M7/54Conversion of dc power input into ac power output without possibility of reversal by dynamic converters
    • H02M7/58Conversion of dc power input into ac power output without possibility of reversal by dynamic converters using mechanical contact-making and -breaking parts to interrupt a single potential
    • H02M7/62Conversion of dc power input into ac power output without possibility of reversal by dynamic converters using mechanical contact-making and -breaking parts to interrupt a single potential with electromagnetically-operated vibrating contacts, e.g. chopper

Definitions

  • FIG. 5 CURRENT CONVERTING CONTACTOR MECHANISM Filed Feb. 8, 1939 3 Sheets-Sheet 3 R64.
  • FIG. 5
  • This invention relates to current converting contactor m and more particularly to a current converting contactor mechanism utilized in combination with A. C. operated devices for enabling operation of such A. 0. device either from a D. C. source or from an A. C. source.
  • A. C. operated devices for enabling operation of such A. 0. device either from a D. C. source or from an A. C. source.
  • an improved current converting mechanism of such type which will automatically supply to an alternating current load to which it is connected alternating current irrespective whether the current converting mechanism is supplied from a D. C. source or an A. C. source.
  • I Fig. l is a diagrammatic diagram of a current converting mechanism and its operating circuits exemplifying one form of the invention
  • Fig. 2 is an elevational view of the mechanism of Fig. 1;
  • Fig. 3 is a vertical cross-sectional view of the device of Fig. 1 along line 3-4 of Fig. 2;
  • Figs. 4 to 7 are views similar to Fig. 1 illustrating other exempliiications of the invention.
  • A. C. devices such as amplifiers, phonograph motors, which are primarily designed to operate with alternating current have frequently to be operated from a direct current source.
  • A. C. devices either from an A. C. source or a D. C. source
  • such devices are often provided with a current convert- 5 ing pole-changin contactor mechanism arranged to convert current from the D. C. source into alternating current pulsations with which the A. C. device is energized.
  • A. C. devices equipped with such current converting contactor 40 mechanism had to be provided with a separate manually operated switch or relay arrangement so as to cut out the current converting contactor mechanism when the device was supplied from an A. C.
  • the current converting contactor mechanism of the invention eliminates such special switching or relay arrangements and the expense and complications connected with the use of additional relays and wiring as well as the other disadvantages inherent in the use of such switching arrangements, and makes possible foolproof operation of a device designed for operation with alternating current when supplied from either a D. C. source or an A. C. source, without requiring any additional switching or relay mechanisms.
  • Figs. 1 to 3 an exempliflcation of the invention as applied to a current converting vibratory contactor mechanism of the polechanging type.
  • the vibratory contactor mechanism comprises a suitable frame it supporting a pair of vibratory reeds ll carrying two sets of contact members l2-l3, ll-lli for cooperation with sets of stationary spring contact members lZli-IIO, Mil-I50 which are insulatingly mounted on the framework to.
  • the vibrating reeds ii are provided with a magnetic armature member I6 cooperating with a suitably arranged electromagnet formed of a core l1 and actuating coil 18 for imparting to the reeds H a vibratory motion when the coil I8 is periodically energized.
  • 3, ll--I I are shown connected to input leads I1, I: that may be supplied either from a direct current source or an alternating current source.
  • the electromagnet core I1 is likewise connected to the input leads I1, I: through a circuit including a stationary interrupter contacts 20 and the vibratory interrupter contact l9 mounted on one of the reeds Ii so that when the reed is in its neutral de-energized position, the energizing circuit from the input leads I1, I: to the actuating coll i8 is completed.
  • the electromagnet is so placed relatively to the armature ii of the reed mechanism that when the input leads I1, I2 are connected to a direct current source, the coil I8 is energized to pull the reed armature IS in the direction of the arrow 22 and break the interrupter contacts 19-20, and thus set the reed into vibrations for alternatingly bringing about the engagement of the opposite sets of contacts Ii -I20, 14-! or "-430 and li-ISII.
  • This periodical vibratory motion of the reeds ll converts the D. C. currents supplied to the input leads I1, I: into alternating current pulsations-delivered through the pairs of stationary '5 contacts IIO-llil and lit-I40 to output leads 01. r sp ctively throu h which an A. C. device. such as an amplifier A, is to be supplied.
  • the amplifier A is shown connected to the output leads 01, 0: through a transformer 30, the secondary winding of which is connected through a contactor II to the amplifier A.
  • the transformer and the other elements of the input circuit of the A. C. device such as the amplifier, are so designed and proportioned that when the input leads I1, I: are connected to a D. C. source for instance 110 volts, the vibratory current converting mechanism will be set into vibratory motion to alternately close .the contact pairs lI-lll, ll-l or the contact pairs lt-lll, ll-lll for converting the direct current into alternating current pulses which are delivered in a suitably smoothed-out form to the operating circuits of the amplifier.
  • the vibratory contact mechanism described above which converts D. C. to A. C. when it is connected to a D. C. source, is provided with a control mechanism so arranged that when its input leads are connected to an A. C. source, it remains stationary and establishes a permanent supply circuit connection from its input leads I1.
  • I to its output leads O1, O2 and to the A. C. apparatus connected thereto.
  • the control arrangement comprises a shoulder member 33, which, in its normal position, does not interfere with the free vibrations of the reeds I I, but which may be actuated, for instance, by means of a pull rod 34, to engage the reeds ii and bend them to establish permanent connections between the contacts "-430 and lB-lill, and thereby establish permanent connections from the input leads I1, I: to the output leads 01, O2, and therethrough to the alternating current device A.
  • the actuating rod 34 may be arranged to be operated, for instance, by an armature 38 pivoted at 88 and arranged to be actuated by an electromagnet formed of a core 31 and a coil 38 to swing the armature 35, against the biasing action of a spring 39, away from its stop 40 towards the magnet core 31 and pull the shoulder member 33 so as to flex the reeds II to the position in which they retain the contacts il-ISO, IB-IBO permanently closed.
  • the transformer may be provided with a suitable voltage tap to which D. C. device is connected by the auxiliary control mechanism when the device is operated from a D. C. source so as to assure that the A. C. device is operated with the required voltage irrespective of whether it is supplied from a D. C. source or an A. C. source.
  • the movement of the armature member 35 is also utilized to connect the A. C. device A to a different transformer tap so as to match the impedance of the A. C. device with the input circuit, for instance, by breaking the connection of the A. C. device A to the transformer at the contact ii and connecting the A. C. device to a transformer tap when the armature is tilted from the stop toward the core 31 into engagement with the contact ll.
  • the actuating coil 38 of the auxiliary control arrangement is arranged to be energized from the input leads A through a series condenser ll only when the input leads 11.1: are connected to an A. C. source.
  • the condenser ll By proportioning the condenser ll so that it forms with the inductance of the electromagnet coil ll a resonant circuit, efiicient operation of the auxiliary electromagnet mechanism 81, 88 under A. C. operating conditions will be assured while preventing its operation when connected to a D. C. source.
  • the auxiliary control electromagnet 31-38 will remain deenergized when the input leads 1;, I: are connected to a D. C. supply and the current converting contactor mechanism will operate with the connections arranged in the way shown in Fig. l to convert the D. C. into alternating current supplied to the amplifier A or some other A. C. device connected to the output leads 01, 0:.
  • the control electromagnet 81, 88 will be immediately energized to actuate the vibratory contacts II, it of the contactor mechanism to permanently connect the input leads I1, I: to the output leads Ol, 02 for supplying A. C. to the A. C. device.
  • control arrangement is also utilized to perform additional switching operations, establishing at the auxiliary contacts 3 I, ll the connections of the A. C. device to diflerent transformer taps for securing automatic conversion from A. C. to D. C. operation and vice versa, and at the same time establish additional circuits required for efilcient operation under the different supply conditions.
  • the armature ll of the auxiliary control magnet 31 is arranged to directly actuate the shoulder 33 by which the reeds I I are moved from their freely vibrating positions to the restrained positions in which contacts ll-Iiil and li-llil are permanently closed for directly connecting the input leads I1, I: to the output leads O1, 02.
  • the electromagnet 31 is provided with a solenoid core I for directly pulling the shoulder 33 to the position in which it bends the reeds II to the position in which the input leads I1, I: are permanently connected to the output leads 01, 0: while at the same time a contactor member 46 associated with the solenoid core ll performs the auxiliary switching operations which have to be performed when changing over from operation with a D. C. supply to an A. C. supply or vice versa.
  • the auxiliary control electromagnet I1 is mounted on a frame member In of the vibratory contactor mechanism so that when energized it attracts an armature member 48 mounted on the reed structure ll so as to bend the reed structure I l to the position in which it establishes a permanent connection from the input leads I1, I: to the output leads 01, O: and perform the auxiliary switching operations.
  • a simple manually operated contactor cam 49 suitably mounted on the supporting frame l0 isarranged to be tilted in the direction of the arrow 50 for bending the reed structure II to a position in which its vibratory contacts are retained in engagement with stationary contacts for establishing permanent connection between the input leads and the output leads when operating with an A. 0. supply source.
  • a transformer having a primary winding and a secondary winding connected to said load circuit, two input leads, a vibrating reed contactor interposed between said input leads and the primary winding of said transformer in such manner that, when said input leads are connected to a direct current source of a predetermined voltage, said contactor is set into operation and an alternating current of a desired voltage and frequency is supplied from the secondary winding of said transformer to said load circuit, an electromagnet for vibrating said reed contactor, a circuit for energizing said electromagnet from said input leads through said contactor, an auxiliary electromagnet for actuating the vibratory element of said reed contactor to a stationary position in which said input leads remain continuously connected to the primary winding of said transformer, and. a circuit for energizing said auxiliary magnet from said input leads only when said input leads are connected to an alternating current source.
  • a transformer having a primary winding and a secondary winding connected to said load circuit, two input leads, a vibrating reed contactor interposed between said input leads and the primary winding of said transformer in such manner that, when said input leads are connected to a direct current source of a predetermined voltage, said contactor is set into operation and an alternating current of a desired voltage and frequency is supplied from the secondary winding of said transformer to said load circuit, an electromagnet for vibrating said reed contactor, a circuit for energizing said electromagnet from said input leads through said contactor, an auxiliary electromagnet for actuating the vibratory element of said reed con-tactor to a stationary position in which said input leads remain continuously connected to the primary winding of said transformer, and a circuit including a serially connected condenser for energizing said auxiliary magnet from said input leads only when said input leads are connected to an alternating current source.

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  • Physics & Mathematics (AREA)
  • Electromagnetism (AREA)
  • Engineering & Computer Science (AREA)
  • Power Engineering (AREA)
  • Relay Circuits (AREA)

Description

Dec. 17, 1940. F. X. DOSTAL 2,225,335
CURRENT CONVERTING CONTACTOR MECHANISM Filed Feb. 8, 1959 3 Sheets-Sheet l 14 5 mo 150 38 37 4O 20 11 T A w m m X 45 I f\ I/ A.C.0R D.C. 1
\NPUT 12 FIGJ INVENTOR. FRANK/Y- 00673 41. BY g'lluae wem A TTORNEYS.
Dec. 17, 1940. F. x. DOSTAL CURRENT CONVERTING CONTACTOR MECHANISM 3 Sheets-Sheet 2 Filed Feb. 8, 1939 INVENTOR. FRANK/ 0057M BY 3 M221 R2120,
ATTORNEYfi.
FIG. 2
FIG-3.
Dec. 17, 1940. F. X. DOSTAL 2,225,335
CURRENT CONVERTING CONTACTOR MECHANISM Filed Feb. 8, 1939 3 Sheets-Sheet 3 R64. FIG. 5
1 E] +/H 50 6 13 11 1s 49. 1
130 130 f f 8 I 4 37 FIG.7. F|G.6
INVENTOR. FRANK/K 0087711.
BY S QCPMZM ATTORNEY} Patented Dec, 17, 1940 PATENT orrlcs 2,225,335 CURRENT CONVERTING CONTACTOR MECHANISM m x. Dental. New
York, N. Y.. auignor to -'1ranl!ormer Corporation of America, New York, N. Y., a corporation of New York Application February 8, 1939, Serial No. 255,239
ZCIa-ims.
This invention relates to current converting contactor m and more particularly to a current converting contactor mechanism utilized in combination with A. C. operated devices for enabling operation of such A. 0. device either from a D. C. source or from an A. C. source. Among the objects of the invention is an improved current converting mechanism of such type which will automatically supply to an alternating current load to which it is connected alternating current irrespective whether the current converting mechanism is supplied from a D. C. source or an A. C. source.
The foregoing and other objects of the invention will be understood from the following description of exempliiications thereof, reference being had to the accompanying drawings, wherein I Fig. l. is a diagrammatic diagram of a current converting mechanism and its operating circuits exemplifying one form of the invention;
Fig. 2 is an elevational view of the mechanism of Fig. 1;
Fig. 3 is a vertical cross-sectional view of the device of Fig. 1 along line 3-4 of Fig. 2; and
Figs. 4 to 7 are views similar to Fig. 1 illustrating other exempliiications of the invention.
Many devices, such as amplifiers, phonograph motors, which are primarily designed to operate with alternating current have frequently to be operated from a direct current source. In order to enable operation of such A. C. devices either from an A. C. source or a D. C. source, such devices are often provided with a current convert- 5 ing pole-changin contactor mechanism arranged to convert current from the D. C. source into alternating current pulsations with which the A. C. device is energized. In the past, A. C. devices equipped with such current converting contactor 40 mechanism had to be provided with a separate manually operated switch or relay arrangement so as to cut out the current converting contactor mechanism when the device was supplied from an A. C. source and to interconnect the current 5 converting contactor mechanism in the supply circuit to the device when it was supplied from a D. C. source. Frequently, such switching mechanism is not thrown to the correct position, bringing about damage to the apparatus or, in less 50 severe cases, the blowing of a fuse. To avoid such difficulties, attempts have been made to provide relay arrangements for automatically cutting out the current converting mechanism when the device is connected to an A. C. source and 55 for interconnecting the current converting mechanism in the supply circuit when the A. C. device is operated from a D. C. source.
The current converting contactor mechanism of the invention eliminates such special switching or relay arrangements and the expense and complications connected with the use of additional relays and wiring as well as the other disadvantages inherent in the use of such switching arrangements, and makes possible foolproof operation of a device designed for operation with alternating current when supplied from either a D. C. source or an A. C. source, without requiring any additional switching or relay mechanisms.
In Figs. 1 to 3 is shown an exempliflcation of the invention as applied to a current converting vibratory contactor mechanism of the polechanging type. The vibratory contactor mechanism comprises a suitable frame it supporting a pair of vibratory reeds ll carrying two sets of contact members l2-l3, ll-lli for cooperation with sets of stationary spring contact members lZli-IIO, Mil-I50 which are insulatingly mounted on the framework to. The vibrating reeds ii are provided with a magnetic armature member I6 cooperating with a suitably arranged electromagnet formed of a core l1 and actuating coil 18 for imparting to the reeds H a vibratory motion when the coil I8 is periodically energized. The reeds ii and their contact pairs i2--| 3, ll--I I are shown connected to input leads I1, I: that may be supplied either from a direct current source or an alternating current source. The actuating coil I! of the electromagnet core I1 is likewise connected to the input leads I1, I: through a circuit including a stationary interrupter contacts 20 and the vibratory interrupter contact l9 mounted on one of the reeds Ii so that when the reed is in its neutral de-energized position, the energizing circuit from the input leads I1, I: to the actuating coll i8 is completed. The core I! of the electromagnet is so placed relatively to the armature ii of the reed mechanism that when the input leads I1, I2 are connected to a direct current source, the coil I8 is energized to pull the reed armature IS in the direction of the arrow 22 and break the interrupter contacts 19-20, and thus set the reed into vibrations for alternatingly bringing about the engagement of the opposite sets of contacts Ii -I20, 14-!" or "-430 and li-ISII.
This periodical vibratory motion of the reeds ll converts the D. C. currents supplied to the input leads I1, I: into alternating current pulsations-delivered through the pairs of stationary '5 contacts IIO-llil and lit-I40 to output leads 01. r sp ctively throu h which an A. C. device. such as an amplifier A, is to be supplied. In the drawings. the amplifier A is shown connected to the output leads 01, 0: through a transformer 30, the secondary winding of which is connected through a contactor II to the amplifier A.
The transformer and the other elements of the input circuit of the A. C. device, such as the amplifier, are so designed and proportioned that when the input leads I1, I: are connected to a D. C. source for instance 110 volts, the vibratory current converting mechanism will be set into vibratory motion to alternately close .the contact pairs lI-lll, ll-l or the contact pairs lt-lll, ll-lll for converting the direct current into alternating current pulses which are delivered in a suitably smoothed-out form to the operating circuits of the amplifier.
In accordance with the invention, the vibratory contact mechanism described above, which converts D. C. to A. C. when it is connected to a D. C. source, is provided with a control mechanism so arranged that when its input leads are connected to an A. C. source, it remains stationary and establishes a permanent supply circuit connection from its input leads I1. I: to its output leads O1, O2 and to the A. C. apparatus connected thereto.
In the exemplifications of the invention shown in Figs. 1 to 3, the control arrangement comprises a shoulder member 33, which, in its normal position, does not interfere with the free vibrations of the reeds I I, but which may be actuated, for instance, by means of a pull rod 34, to engage the reeds ii and bend them to establish permanent connections between the contacts "-430 and lB-lill, and thereby establish permanent connections from the input leads I1, I: to the output leads 01, O2, and therethrough to the alternating current device A.
The actuating rod 34 may be arranged to be operated, for instance, by an armature 38 pivoted at 88 and arranged to be actuated by an electromagnet formed of a core 31 and a coil 38 to swing the armature 35, against the biasing action of a spring 39, away from its stop 40 towards the magnet core 31 and pull the shoulder member 33 so as to flex the reeds II to the position in which they retain the contacts il-ISO, IB-IBO permanently closed.
Since a pole-changing vibratory current converting contactor mechanism of the type de-' scribed above gives a different effective A. C. voltage than the D. C. input voltage, the transformer may be provided with a suitable voltage tap to which D. C. device is connected by the auxiliary control mechanism when the device is operated from a D. C. source so as to assure that the A. C. device is operated with the required voltage irrespective of whether it is supplied from a D. C. source or an A. C. source.
In accordance with the invention, the movement of the armature member 35 is also utilized to connect the A. C. device A to a different transformer tap so as to match the impedance of the A. C. device with the input circuit, for instance, by breaking the connection of the A. C. device A to the transformer at the contact ii and connecting the A. C. device to a transformer tap when the armature is tilted from the stop toward the core 31 into engagement with the contact ll.
As shown in Fig. l, the actuating coil 38 of the auxiliary control arrangement is arranged to be energized from the input leads A through a series condenser ll only when the input leads 11.1: are connected to an A. C. source. By proportioning the condenser ll so that it forms with the inductance of the electromagnet coil ll a resonant circuit, efiicient operation of the auxiliary electromagnet mechanism 81, 88 under A. C. operating conditions will be assured while preventing its operation when connected to a D. C. source.
v.With such arrangement, the auxiliary control electromagnet 31-38 will remain deenergized when the input leads 1;, I: are connected to a D. C. supply and the current converting contactor mechanism will operate with the connections arranged in the way shown in Fig. l to convert the D. C. into alternating current supplied to the amplifier A or some other A. C. device connected to the output leads 01, 0:. However, if the input leads I1, I: are connected to an A. C. source, the control electromagnet 81, 88 will be immediately energized to actuate the vibratory contacts II, it of the contactor mechanism to permanently connect the input leads I1, I: to the output leads Ol, 02 for supplying A. C. to the A. C. device.
Furthermore, the control arrangement is also utilized to perform additional switching operations, establishing at the auxiliary contacts 3 I, ll the connections of the A. C. device to diflerent transformer taps for securing automatic conversion from A. C. to D. C. operation and vice versa, and at the same time establish additional circuits required for efilcient operation under the different supply conditions.
The principles of the invention as described in connection with its exemplifications shown in Figs. 1 to 3 will suggest many other modifications thereof.
Thus, in the modifications shown in Fig. 4, the armature ll of the auxiliary control magnet 31 is arranged to directly actuate the shoulder 33 by which the reeds I I are moved from their freely vibrating positions to the restrained positions in which contacts ll-Iiil and li-llil are permanently closed for directly connecting the input leads I1, I: to the output leads O1, 02.
In the modification of Fig. 5, the electromagnet 31 is provided with a solenoid core I for directly pulling the shoulder 33 to the position in which it bends the reeds II to the position in which the input leads I1, I: are permanently connected to the output leads 01, 0: while at the same time a contactor member 46 associated with the solenoid core ll performs the auxiliary switching operations which have to be performed when changing over from operation with a D. C. supply to an A. C. supply or vice versa.
In the modificationsof Fig. 6. the auxiliary control electromagnet I1 is mounted on a frame member In of the vibratory contactor mechanism so that when energized it attracts an armature member 48 mounted on the reed structure ll so as to bend the reed structure I l to the position in which it establishes a permanent connection from the input leads I1, I: to the output leads 01, O: and perform the auxiliary switching operations.
The idea underlying the invention, namely, the
such as shown in Fig. '7, in which a simple manually operated contactor cam 49 suitably mounted on the supporting frame l0 isarranged to be tilted in the direction of the arrow 50 for bending the reed structure II to a position in which its vibratory contacts are retained in engagement with stationary contacts for establishing permanent connection between the input leads and the output leads when operating with an A. 0. supply source.
The invention is not limited to the details of construction and arrangements described herein, and many modifications thereof will suggest themselves to those skilled in the art. It is accordingly desired that the appended claims be given a broad construction commensurate with the scope of the invention.
I claim:
1. In combination with a load circuit designed for operation with alternating currents, a transformer having a primary winding and a secondary winding connected to said load circuit, two input leads, a vibrating reed contactor interposed between said input leads and the primary winding of said transformer in such manner that, when said input leads are connected to a direct current source of a predetermined voltage, said contactor is set into operation and an alternating current of a desired voltage and frequency is supplied from the secondary winding of said transformer to said load circuit, an electromagnet for vibrating said reed contactor, a circuit for energizing said electromagnet from said input leads through said contactor, an auxiliary electromagnet for actuating the vibratory element of said reed contactor to a stationary position in which said input leads remain continuously connected to the primary winding of said transformer, and. a circuit for energizing said auxiliary magnet from said input leads only when said input leads are connected to an alternating current source. v
2. In combination with a load circuit designed for operation with alternating currents, a transformer having a primary winding and a secondary winding connected to said load circuit, two input leads, a vibrating reed contactor interposed between said input leads and the primary winding of said transformer in such manner that, when said input leads are connected to a direct current source of a predetermined voltage, said contactor is set into operation and an alternating current of a desired voltage and frequency is supplied from the secondary winding of said transformer to said load circuit, an electromagnet for vibrating said reed contactor, a circuit for energizing said electromagnet from said input leads through said contactor, an auxiliary electromagnet for actuating the vibratory element of said reed con-tactor to a stationary position in which said input leads remain continuously connected to the primary winding of said transformer, and a circuit including a serially connected condenser for energizing said auxiliary magnet from said input leads only when said input leads are connected to an alternating current source.
FRANK X. DOSTAL.
US25523939 1939-02-08 1939-02-08 Current converting contactor mechanism Expired - Lifetime US2225335A (en)

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Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2651729A (en) * 1949-09-29 1953-09-08 Bendix Aviat Corp Electrical apparatus
US2677798A (en) * 1950-10-09 1954-05-04 Bekey Andrew Electrical supply system for operating loads
US3061736A (en) * 1960-10-27 1962-10-30 American Optical Corp Circuit for switching alternating current power sources

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2651729A (en) * 1949-09-29 1953-09-08 Bendix Aviat Corp Electrical apparatus
US2677798A (en) * 1950-10-09 1954-05-04 Bekey Andrew Electrical supply system for operating loads
US3061736A (en) * 1960-10-27 1962-10-30 American Optical Corp Circuit for switching alternating current power sources

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